Inductively coupled data and power transfer system and apparatus

ABSTRACT

The present invention provides a system and apparatus for transferring electronic data and/or power from one station to another by means of a transportable pod comprising a solid state memory device and further provided with an inductively linked, electrically insulated connector. The transportable pod comprises a battery which is used to power a remote host docking station, which may be used in an underwater environment for the collection of subsea data. The transportable pod can be transferred alternately from a home docking station, where it is charged up, and where it&#39;s stored data is uploaded and to a remote host docking station where is provides power, and where it collects and stores data collected by the remote host docking station.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of GB 0823436.1 filed Dec. 23, 2008,entitled Inductively Coupled Memory Transfer System, by Mark Rhodes andBrendan Hyland, which application is fully incorporated herein byreference.

FIELD OF USE

The present invention relates to a system for transferring electronicdata and/or power from one station to another by means of atransportable unit provided with a solid state memory device a portableenergy source and an inductively coupled, electrically insulatedconnector.

BACKGROUND TO THE INVENTION

Universal Serial Bus (USB) “memory sticks” have become an extremelyconvenient and practical method of transferring electronic data betweencomputer systems. Recently the capacity supported by these smalltransportable devices has increased to many tens of Gigabytes and nodoubt will continue to expand further over time. These devices typicallyconsist of a USB interface device which supports several NAND flashmemory integrated circuits. Power is supplied over the USB standardconnector which also supports the two wire high speed serial datainterface. Several inventions have sort to devise mechanical protectionmechanisms for the USB connector. For example U.S. Patent ApplicationPublication 2008/108245A1 “Protection mechanism for terminal of memorystick adapter” Shu-Chin, describes a retracting cover for the terminalsof a memory stick device. The mechanism taught by Shu-chin provides ameans to minimize mechanical damage of the connector contacts.

Contamination of the electrically conductive terminals is anotherfailure mechanism of the USB memory stick connector. The connectorrelies on metal to metal conductive contact and this can fail due tocontamination with insulating material, which prevents conductivecontact, or contamination with conductive material, which can introducea short circuit between adjacent pins.

There is a need for a solid state portable memory device integrated withan electrically insulated connector system that overcomes theselimitations.

Electrical connections are a challenging aspect of underwater electricalsystem design; the standard implementation of an electrical connectorincludes terminals or pins which make conductive electrical contact witheach other. Such terminals and pins are subject to corrosion andcontamination; corrosion of the terminals produces poor or intermittentcontact and failure of the connector. Furthermore, in under waterapplications, water must be excluded from the conductive contacts toprevent short circuits due to the partially conductive nature of water.Thus, wet mating connections present even greater challenges to overcomesince water must be expelled from the conductive contacts during matingand since care must be taken to ensure an electrical signal is notapplied to the connector while the contacts are exposed to the water andbefore the connection is made. A connector which does not rely upondirect conductive contact would avoid these problems.

Additionally, any multi pin connector must be rotationally aligned toensure registration of the intended cross connections. This requirementcan be problematic in underwater applications, particularly where theconnection point is not readily accessible by an operator such as when aconnection is established by an autonomous system deep in the ocean.Slip ring connectors have been designed to avoid this issue buttypically employ conductive contacts which are subject to corrosion andcontamination as described herein. An electrically insulated data andpower connection which mates independent of angular alignment would bebeneficial in many underwater applications.

In the field of oil and gas exploration, seismic imaging over a largearea of the seabed is an important method for optimization of oil andgas production, and for the assessment of the capacity of a particularfield. The article entitled “Breakthrough for repeated seismic” byHalfdan Carstens, Geo ExPro; September 2004; pp 26-29,http://www.geoexpro.com/sfiles/8/21/6/file/Valhall_(—)26-29.pdf outlinesa system for the gathering of seismic imaging data over a large area ofthe seabed.

The system for undersea seismic imaging taught by Carstens comprises anetwork or array of seismic monitoring stations which includesensors—such as geophones and hydrophones located at evenly spacedintervals (typically 50 metres) spanning a given area around a field ofunderwater exploration. The seismic monitoring stations taught beCarstens are linked together by a wired network of cable, and the datacollected from the seismic sensors is gathered and stored by a mainprocessing unit which is connected into the wired network; the wirednetwork of cable also provides a means for the synchronization of thevarious sensors in the network.

Typically the seismic sensors and seismic monitoring stations recorddata at regular time intervals. Over the duration of one ‘survey’ thedata collected per station could be in the order of one Gigabyte. Thetransfer of one Gigabyte of data in a reasonable length of time producesa requirement of the wired network for a data rate which is in the orderof hundreds of kilobits per second.

The benefits of rolling out such a wired seismic motoring network areoptimization of oil and gas production, the generation of information onthe optimum drilling locations and the generation of information onfield capacity and yield. The drawbacks of installing such a wiredseismic motoring network are the cost of network deployment and the costof maintenance thereof. It would be preferable to deploy a network ofisolated, free-standing seismic monitoring stations, where power anddata transfer are provided by some alternative means to a wired network.

SUMMARY OF THE INVENTION

According to one aspect of the present invention, there is provided asystem for transferring electronic data from a first station to a secondstation by means of a transportable pod comprising a solid state memorydevice and an inductively coupled, electrically insulated connector.

According to another aspect of the present invention, there is provideda system for transferring electrical power through the inductivelycoupled connector from a battery provided within the transportable podbetween the first and second stations.

According to another aspect of the present invention, there is provideda transportable pod comprising a battery, a solid state memory device,each of which is electrically coupled to an inductively coupledconnector of the transportable pod via control electronic circuitry.During use, electrical power is transferred between the battery of thepod and an external docking station via the inductively coupledconnector of the pod. Furthermore, during use, data is transferredbetween the solid state memory device of the pod and an external dockingstation via the same inductively coupled connector.

The solid state memory device of the transportable pod may beimplemented using a flash memory device; hard disk device or alternativemeans of electronic storage.

The transportable pod of the present invention is particularly suited toapplications where the remote host docking station is locatedunderwater.

In some embodiments the control electronic circuitry coupling thebattery to the inductively coupled connector of the transportable pod isa power transfer sub-system comprising an AC/DC converter or a DC/ACconverter.

In other embodiments the control electronic circuitry coupling thememory device of the transportable pod to the inductively coupledconnector is a data interface comprising a high pass filter and a modemoperable to decode a data stream received from the external dockingstation or to encode a data stream to be transferred to docking station.

In one embodiment, there is provided a release mechanism that isactivated remotely to initiate de-mating of the transportable pod fromthe remote host docking station. Remote activation may be via radiocommunications. For embodiments where the remote host docking station islocated underwater, remote activation may be via acoustic subseacommunications, or subsea radio communications.

According to another embodiment of the present invention, thetransportable pod comprising a solid state memory device and a batteryis arranged to be positively buoyant when immersed in water. Thus, forexample, when the remote release de-mates the transportable pod from anunderwater remote host docking station the transportable pod will floatto the surface of the water to allow recovery of the transportable podfrom the surface of the water.

In some applications, the transportable pod will remain tethered to thehost system as it floats to the surface of the water to ensure itremains close to the expected recovery point. The transportable pod maybe provided with a spooled line that is attached to the remote hostsystem and which is deployed as the pod rises to the surface.

In another embodiment of the present invention, there is provided ameans for providing the transportable pod with positive buoyancy inresponse to a remote release signal. This may be implemented using acompressed gas canister which inflates a bladder contained in orattached to the outside of the transportable pod to create positivebuoyancy.

In some embodiments, the docking station forms part of a remote hostsystem comprising an inductively coupled connector that can mate to theinductively coupled connector of the transportable pod thereby providinga means for transferring electrical power from the pod battery to thehost docking station via the inductive connectors of the pod and thehost station, and also providing means for transferring data from thehost station to the transportable pod and/or data from the transportablepod to the host station.

In other embodiments of the present invention, there is provided adocking station that forms part of a home station comprising aninductively coupled connector that can mate to the inductively coupledconnector of the transportable pod thereby providing means fortransferring charge to the pod battery, and for transferring data to andfrom the pod memory device.

The system of the present invention typically has applications where anelectrically conductive contact based connector system would be exposedto contaminants.

Applications of the present invention include any harsh environment, andthe inductively coupled data and power transfer systems and apparatusdescribed herein are particularly suited to underwater applications.

In another embodiment of the present invention, there is provided amechanical retention mechanism and mechanical release mechanism for thetransportable pod.

According to another embodiment of the present invention, there isprovided a remote host docking station comprising multiple inductivelycoupled connectors each of which are pre-loaded with transportable pods,and system control circuitry which can detach a spent pod after itsdeployment period and which can switch to a fresh pod for data and powertransfer to allow data collection without the need for a system toreplace memory pods.

In one embodiment the home docking station and host docking station maybe further provided with Universal Serial Bus (USB) interfaces.

Embodiments of the present invention will now be described withreference to the accompanying figures in which:

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 shows a functional block diagram of the electronic circuitry of atransportable pod according to an embodiment of the present invention;

FIG. 2 shows a block diagram of an inductively coupled data and powertransfer system according to an embodiment of the present invention;

FIG. 3 shows the mechanical construction of a female inductive connector30 and a male inductive connector 31 for use in the embodiment of thepresent invention depicted in FIG. 2;

FIG. 4 shows a three dimensional illustration of the female inductiveconnector and the male inductive connector of FIG. 3, further comprisinga Universal Serial Bus (USB) pigtail for connection to any conventionalitem of computer hardware;

FIG. 5 shows a transportable pod comprising a male inductive connector,mated to a female inductive connector 54 of a docking station accordingto an embodiment of the present invention;

FIG. 6 shows a block diagram of an inductively coupled data and powertransfer system comprising an array of sensors and a docking stationwhich mates with a transportable pod according to an embodiment of thepresent invention.

DETAILED DESCRIPTION

FIG. 1 is a functional block diagram of a transportable pod according toan embodiment of the present invention. Block 10 represents theinductively coupled connector which is shown in further detail in FIG.3. Data interface 11 processes a modulated signal which is received froman external docking station (not shown) via inductively coupledconnector 10 and formats the data for presentation at the input ofmemory device 12. Similarly, data interface 11 can read stored data inmemory device 13 and modulate the data for transfer to an externaldocking station (not shown) via inductively coupled connector 10 so asto provide bi directional data exchange between the external dockingstation (not shown) and memory device 12 of the transportable pod of thepresent invention. Data interface 11 might include such electroniccircuitry as a modem to modulate data from memory device 12 for transferover inductive connector 10 and to de-modulate data received viainductive connector 10 for interfacing with memory device 12. Powertransfer sub-system 13 couples battery 14 to inductive connector 10 ofthe transportable pod and comprises electronic circuitry for coupling ACelectrical power received at inductive connector 10 to battery 1 suchcircuitry might include an AC/DC converter; power transfer sub-system 13similarly comprises electronic circuitry for coupling DC power frombattery 14 to AC electrical power at inductive connector 10, suchcircuitry might include a DC/AC converter.

FIG. 2 shows a block diagram of an inductively coupled data and powertransfer system according to an embodiment of the present invention. Theinductively coupled data and power transfer system comprisestransportable pod 201 which is mated with docking station 200. Dockingstation 200 may be a remote host docking station—for example locatedunderwater and comprising one or more sensors for data collection;alternatively, docking station may be a home station—for example locatedon a base station. Transportable pod 201 comprises memory device 18,battery 17 and inductively coupled connector 19. During use, inductiveconnector 19 transfers power and data between docking station 200 andmemory device 18 of transportable pod 201. AC to DC converter 16 is usedto provide DC power to battery 17 for charging. On the other hand DC toAC converter 15 is used to convert DC from battery 17 to AC for couplingto docking station 200 via inductive connector 19. High pass filter 27separates the power transfer signal from a modulated carrier signal thatsends and received data via inductive connector 19. Communications modem28 modulates data received from memory device 18 for transfer overinductive connector 19 and de-modulates data received via inductiveconnector 19 for interfacing with memory device 18.

Docking station 200 comprises data interface 20 and communications modem21 connected to inductive connector 26 via high pass filter 25 andfurther comprises home charging interface 22 and/or host power interface23. For systems in applications where docking station 200 is a remotehost station, home charging interface is typically omitted. Similarlyfor systems where docking station 200 is a home station, host powerinterface 23 is typically omitted. High pass filter 25 separates thepower transfer signal from a modulated carrier signal that sends andreceived data via inductive connector 26. Home charging interfacecomprises a DC to AC converter to convert DC power which it receives atan input of home docking station 200 to AC power for coupling totransportable pod 201 via inductive connectors 26 and 19. The powercoupled to transportable pod 201 via inductive connectors 26 and 19 isused to charge battery 17 of transportable pod 201. Host charginginterface comprises an AC to DC converter to convert AC power receivedfrom transportable pod 201 via inductive connectors 19 and 26 and toprovide DC power to remote host docking station 200. DC power providedto remote host docking station 200 from transportable pod 201 viainductive connectors 19 and 26 can be used to power communications modem21, data interface 20 and any sensors or other data collection deviceswhich are connected to docking station 200. Data collected by remotehost docking station 200 is transferred to memory device 18 oftransportable pod 201 via communications modem 21, high pass filter 25,inductive connectors 26 and 19, high pass filter 27, and communicationsmodem 28.

The transportable pod of the present invention depicted in FIG. 1 andthe inductively coupled data and power transfer system of the presentinvention depicted in FIG. 2 is particularly suitable for the transferof data and electrical power between a home docking station and a remotehost docking station via a transportable pod where the remote hostdocking station is located underwater.

In an example usage case, a transportable pod is provided with a solidstate memory device, a battery supply and an inductive connector system.An unmanned underwater vehicle (UUV) transports the transportable pod toa remotely deployed sensor (RDS) unit on the seabed. The RDS has beendeployed for a period of time, it draws its power from the batterywithin the transportable pod and stores recorded data within the solidstate memory device of the transportable pod. The UUV detaches apreviously deployed first transportable pod from the RDS by transmittinga short range underwater radio signal to initiate release of the pod.The UUV recovers the first transportable pod and replaces it with asecond unit which it has brought from the surface of the sea. The firstunit is recovered for analysis of recorded data. The second unit has afully charged battery which provides power to the RDS for the nextdeployment period. The RDS continues to record data on the memory deviceof the second transportable pod.

In another system application the transportable pod and host dockingstation form part of a system for recovering data and/or deliveringpower to a remotely deployed subsea seismic sensor or array of sensors.Sensors may be spaced at known intervals along a subsea cable that isarranged to carry data and power from each sensor to a host dockingstation. A transportable pod mated with the docking station providespower for the connected sensor array and stores recorded data from thesensors. The transportable pod can be exchanged periodically asdescribed above.

FIG. 3 shows the mechanical construction of the inductively coupledconnectors 19 and 26 of FIG. 2. Inductively coupled connector 19 of FIG.2 is represented by male inductive connector 31 of FIG. 3 andinductively coupled connector 26 of FIG. 2 is represented by femaleinductive connector 30 of FIG. 3. The upper section of FIG. 3 shows across section side view of both female connector 30 and male connector31. The lower section of FIG. 3 shows a cross section bottom view offemale connector 30. Line A-A indicates the position of the crosssection shown in the lower part of FIG. 3. Female inductive connector 30comprises a coil of wire 32 wound on a core 33 formed of a materialhaving a high magnetic permeability. A material having a relativepermeability greater than 10 would be suitable for this application. Theentire female connector 30 is encased in a housing 34 formed of anelectrically insulating material. Male inductive connector 31 comprisesa coil of wire 35 wound on a core 37 formed of a material having a highmagnetic permeability. A relative permeability greater than 10 would besuitable for this application. The entire male connector 31 is encasedin a housing 36 formed of an electrically insulating material. Maleconnector 31 and female connector 30 are designed so that the mechanicalinterface presented by one is the inverse of the other, so that the twoconnectors fit together snugly. When female connector 30 is mated withmale connector 31, magnetic cores 33 and 37 are aligned so that the coil32 of female inductive connector 30 and the coil 35 of male inductiveconnector 31 are strongly inductively coupled.

FIG. 4 shows a three dimensional illustration of the female inductiveconnector 40 and the male inductive connector 41 of FIG. 3, furthercomprising a Universal Serial Bus (USB) pigtail 43, with USB type Aconnector 44 for connection to any conventional item of computerhardware.

FIG. 5 shows a transportable pod 55 for underwater use comprising a maleinductive connector 56, mated to a female conductive connector 54 of adocking station (not shown) with a captive connection 51, 52, 53 whichmay be released by a radio signal. Flange 51 supports wire link 52 whichconnects to flange 53 thereby retaining transportable pod 55 in contactwith connector 55. At the moment when transportable pod 55 is to berelease from connector 54 a current is passed through wire link 52 whichis sufficient to fuse or break the wire resulting in release of thetransportable pod from connector 54. The release command may betransmitted wirelessly by an RF signal or by an acoustic signal. Thetransportable pod 55 comprises a float 50 attached to an upwardly facingside thereof, so that transportable pod 55 is positively buoyant andwill float to the surface of the water when the release mechanism isactivated.

FIG. 6 shows a block diagram of an inductively coupled data and powertransfer system comprising an array of sensors wired to a dockingstation according to another embodiment of the present invention. Thesystem of FIG. 6 comprises an array of sensor nodes 62 wired to adocking station 63 comprising an inductively coupled connector (notshown) that mates with a an inductively coupled connector (not shown) ofa transportable pod 61 for collection by a UUV. Sensor nodes 62 may beseismic survey sensors that are spaced along and connected to data andpower cable 65. Data and power cable 65 acts to control the spacing ofsensors during deployment, supplies power from the transportable pod 61via the inductively coupled connectors of the pod 61 and the dockingstation 63 to each sensor node 62 and similarly transfers data from eachsensor node 62 to the transportable pod 61 via the inductively coupledconnectors of the docking station 63 and pod 61. Data can also betransferred from a memory storage device of transportable pod 61,through host docking station 63 to each sensor 62 via the inductivelycoupled connectors of the docking station 63 and pod 61 and via data andpower cable 65. UUV 60 periodically exchanges memory pod 61 with a freshunit.

Those skilled in the art will understand that any form of data storagedevice or data storage medium other than those specified in theforegoing examples could be used to realize the present invention.

Moreover, those skilled in the art will understand that the term batteryis used so as to encompass any form of portable energy source. Such anenergy source might be a rechargeable battery, a long life battery, acapacitive device or a fuel cell.

The inductively coupled data and power transfer systems described hereinare generally suited to systems and applications which are deployed inunderwater environments. However, there is no reason why the system ofthe present invention would be limited to such underwater systems andapplications.

Moreover, the above descriptions of the specific embodiments are made byway of example only and are not for the purposes of limitation. It willbe obvious to a person skilled in the art that in order to achieve someor most of the advantages of the present invention, practicalimplementations may not necessarily be exactly as exemplified and mayinclude variations within the scope of the present invention.

1. A transportable pod; said transportable pod comprising a battery, asolid state memory device, and an inductively coupled connector, saidbattery and said solid state memory device being electrically coupled tosaid inductively coupled connector via control electronic circuitrywherein, during use, electrical power is transferred between saidbattery and a docking station external to said pod via said inductivelycoupled connector and data is transferred between said docking stationand said solid state memory device via said inductively coupledconnector.
 2. A transportable pod according to claim 1 wherein saidinductively coupled connector is electrically insulated.
 3. Atransportable pod according to claim 1 wherein said transportable pod isadapted to operate in an underwater environment.
 4. A transportable podaccording to claim 1, said control electronic circuitry comprising afilter circuit which separates a low frequency electrical powercomponent to be coupled to or from said battery and a high frequencydata component to be coupled to or from said memory device.
 5. Atransportable pod according to claim 1, said control electroniccircuitry comprising a DC to AC converter.
 6. A transportable podaccording to claim 1, said control electronic circuitry comprising an ACto DC converter.
 7. A transportable pod according to claim 1, saidcontrol electronic circuitry comprising a modem operable to decode adata stream received from said docking station or to encode a datastream to be transferred to said docking station.
 8. A transportable podaccording to claim 1 said transportable pod further comprising a captivemechanical interface to facilitate connection of said pod to saiddocking station.
 9. A transportable pod according to claim 1 wherein theaverage density of said pod is less than that of water.
 10. Aninductively coupled data and power transfer system comprising thetransportable pod of claim 1 and a remote host docking stationcomprising an inductively coupled connector wherein during use, saidbattery of said pod provides electrical power to said remote hostdocking station via said respective inductively coupled connector ofsaid pod and data is received from said remote host docking station viasaid respective inductively coupled connector of said docking stationand said pod and is stored on said memory device.
 11. An inductivelycoupled data and power transfer system according to claim 10 whereinsaid received data from said remote host docking station is collectedfrom a sensor connected to said remote host docking station.
 12. Aninductively coupled data and power transfer system according to claim 10wherein said remote host docking station is located underwater.
 13. Aninductively coupled data and power transfer system according to claim 10further comprising an array of sensors connected to said remote hostdocking station, wherein, during use, said transportable pod provideselectrical power to said remote host docking station via said respectiveinductively coupled connector of said pod and said docking station, anddata from said array of sensors is received via said respectiveinductively coupled connector of said docking station and said pod andis stored in said solid state memory device of said pod.
 14. Aninductively coupled data and power transfer system according to claim 10wherein said transportable pod further comprises a captive mechanicalinterface to facilitate connection of said pod to said docking station.15. An inductively coupled data and power transfer system according toclaim 10 wherein said pod further comprises a mechanism for detachmentof said pod from said remote host docking station.
 16. An inductivelycoupled data and power transfer system according to claim 15 whereinsaid mechanism for detachment of said pod from said remote host dockingstation is triggered by a radio signal.
 17. An inductively coupled dataand power transfer system according to claim 15 wherein said mechanismfor detachment of said pod from said remote host docking station istriggered by an acoustic signal.
 18. An inductively coupled data andpower transfer system according to claim 10 wherein said remote hostdocking station is located underwater and wherein said pod furthercomprises an expandable bladder which is inflated after detachment ofsaid pod from said remote host docking station.
 19. An inductivelycoupled data and power transfer system according to claim 10 whereinsaid remote host docking station is located underwater and wherein saidpod further comprises a spooled line that is attached to said remotehost station and which is deployed as said transportable pod rises tothe surface.
 20. An inductively coupled data and power transfer systemcomprising the transportable pod of claim 1 and a home docking stationcomprising an inductively coupled connector wherein, during use saidbattery of said pod is charged by said home docking station via saidrespective inductively coupled connector of said home docking stationand said pod, and stored data in said solid state memory device of saidpod transferred to said home docking station via said respectiveinductively coupled connector of said pod and said home docking station.21. An inductively coupled data and power transfer system; said systemcomprising a transportable pod and a docking station, said podcomprising a battery a solid state memory device, each coupled to aninductively coupled connector, said docking station also comprising aninductively coupled connector wherein, during use, data and electricalpower is transferred from said pod to said docking station or to saidpod from said docking station via said respective inductively coupledconnector of said pod and said docking station.
 22. An inductivelycoupled data and power transfer system; said system comprising a homestation and a remote host station and further comprising a transportablepod, said transportable pod comprising a battery, a solid state memorydevice, each coupled to an inductively coupled connector, said homestation comprising an inductively coupled connector and said remote hoststation also comprising an inductively coupled connector wherein, duringuse, electrical power is transferred from said home station to saidremote host station via said battery of said pod and via each saidinductively coupled connector of said home station, said pod and saidremote station and data is transferred from said remote host station tosaid home station via said memory device of said pod and via each saidinductively coupled connector of said home station, said remote stationand said pod.
 23. An inductively coupled data and power transfer systemaccording to claim 22 wherein said transfer of power and data takesplace through said pod alternately docking on said home station and saidremote host station.